JP3506234B2 - Powder material supply device and exhaust gas treatment device - Google Patents

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a powder and granular material supply apparatus and an exhaust gas processing apparatus, and more particularly to a powder and granular material supply apparatus for supplying powder and granular materials downward, and an exhaust gas processing apparatus including the powder and granular material supply apparatus. Regarding the device.

[0002]

2. Description of the Related Art As a conventional powder and granular material feeder, in addition to a general-purpose powder hopper, for example, Japanese Patent Application Laid-Open No. 8-
An example is a catalyst (powder granule) supply unit that constitutes the dry desulfurization / denitration apparatus described in Japanese Patent No. 332347. The catalyst supply unit is formed by connecting a plurality of pipe chutes to the upper distribution hopper, and aims to make the particle size distribution of the catalyst uniform in the moving bed disposed below these chutes. Further, by this, the uneven flow of the exhaust gas is sufficiently prevented and the reduction of the exhaust gas treatment efficiency is sufficiently suppressed.

[0003]

By the way, the dry desulfurization / denitration apparatus described in the above publication has the above-mentioned excellent effects and is sufficiently satisfactory from the viewpoint of exhaust gas treatment performance. is there. On the other hand, the present inventors
As a result of earnest studies and studies on the conventional device, it was found that the chute tends to be gradually worn away with the operation of the device although it is slight. Such an event does not greatly affect the exhaust gas treatment performance of the dry desulfurization / denitration equipment, but from the viewpoint of improving the maintainability and economic efficiency by reducing the replacement frequency of the members that make up the equipment, this point It was concluded that further improvement was desirable.

Therefore, the present invention has been made in view of the above circumstances, and an object thereof is to provide a powdery- or granular-material supplying device capable of reducing wear when the powdery or granular material is supplied. It is another object of the present invention to provide an exhaust gas treatment device capable of reducing the frequency of exchanging members constituting the device and improving maintainability and economic efficiency while sufficiently preventing uneven flow of exhaust gas.

[0005]

In order to achieve the above object, the present inventor has conducted further studies, and as a result, the wear of the chute is caused by the chute surface on which the granular material such as the catalyst flows and the granular material. It was found that the dynamic contact (rubbing, rubbing, etc.) of the is one of the main factors. Further, in order to prevent such wear, it is easily conceivable to provide a liner material for wear prevention on the chute surface, but this causes complication of the member configuration and increase of the member cost, and in the future. Wear of the liner material itself becomes a problem. Then, based on these findings, earnest research was conducted to complete the present invention.

That is, the powdery- or granular-material feeder according to the present invention supplies powdery or granular materials downward, and has a main plate portion extending at a predetermined angle with respect to the horizontal, and a main plate portion above the main plate portion. And a plurality of sub-plate portions arranged at predetermined intervals along the extending direction of the main plate portion and provided with a chute to which the powder or granular material is supplied. And

In the powdery- or granular-material feeder thus constructed, when the powdery or granular material is supplied to the main plate portion of the chute, the main plate portion has a predetermined angle with respect to the horizontal, that is, the main plate portion is inclined. Since the particles are arranged in such a manner, the powder and granules flow down along the main plate portion. A part of the granular material is blocked (blocked) by being blocked (blocked) by a plurality of sub-plate portions protruding from the main plate portion, and deposited on the entangled portion between the main plate portion and the sub-plate portion. As a result, the entire upper surfaces of the main plate portion and the sub-plate portion can be covered with the granular material,
Further, the supplied powder and granules flow down along the chute so as to overflow and slide down on the deposited powder and particles without directly and dynamically contacting the main plate portion and the sub-plate portion.

Further, since the powder and granules can flow down along the chute, a structure in which the upper side of the main plate portion is opened is possible.
In this case, the possibility of blockage is lower than that of the conventional pipe chute. Further, the entire periphery of the powdery or granular material feeder may be covered with a lid or a casing. By doing this, even if a chute breaks or breaks in the chute, it is possible to prevent the powder particles from escaping to the outside or leaking to the outside even if applied to a system using gas. Can be done.

Further, it is preferable that the main plate portion is provided so as to satisfy the relationship represented by the following formula (1); θa ≦ θs ≦ θa + 30 ° (1). Here, in the formula, θa represents the angle of repose formed by the powdery particles, and θs represents the above-mentioned predetermined angle formed by the main plate portion with respect to the horizontal direction. In this way, it is possible to prevent the fluidity of the powder or granules from decreasing and prevent the flow rate of the powder or granules from increasing excessively.

Further, it is more preferable that the sub-plate portion is provided so as to satisfy the relationship represented by the following formula (2); Lp ≦ H × 4 (2). Here, in the formula, Lp represents the above-mentioned predetermined interval of the plurality of sub plate portions, and H represents the height of the sub plate portion from the main plate portion surface. By doing so, powder particles are easily deposited on the entire upper surface of the main plate portion, exposure of the upper surface of the main plate portion is suppressed, and wear of the chute due to dynamic contact with the powder particles can be reliably prevented.

Furthermore, a plurality of chutes are provided,
It is preferable to further include a stage that connects a plurality of chutes at the upper ends of the chutes and a hopper unit that is provided above the stages and into which the powder and granules are introduced.

Generally, when powder particles having a particle size distribution fall freely, they are accumulated so as to form a free surface having an angle of repose depending on the particle size distribution, material, shape, and the like. At this time, particles having a large particle diameter tend to gather in the peripheral portion, and particles having a small particle diameter tend to gather in the central portion. Since the powder and granules dropped from the chute show the same tendency, the powder and granules supplied downward from the chute and accumulated have a nonuniform particle size as a whole. If this happens, the target of powder and granular material supply will be dry desulfurization /
In the case of a denitration device, as described in the prior art publication, there is a possibility that gas drift will occur.

On the other hand, by appropriately arranging a plurality of chutes, the powdery particles can be supplied from a plurality of locations, so that it is possible to alleviate or prevent the nonuniformity of the overall particle size of the powdery particles to be accumulated. Further, when these chutes are connected to each other by a stage at the upper end and the powder and granules are introduced from the hopper to the stage, the powder and granules accumulated on the stage overflow and are supplied to the chutes substantially uniformly. Therefore, the amount and the particle size of the powder particles supplied downward from each chute can be favorably made uniform.

At this time, it is desirable that the hopper section has an adjustment margin for adjusting the installation position along the horizontal direction. According to this structure, it becomes easy to match the falling position of the granular material from the hopper with the center of the stage.
Thereby, there is an advantage that the powder and granules can be supplied to each chute more evenly. Therefore, it is possible to further homogenize the amount and particle size of the powder or granular material supplied downward from each chute.

In the exhaust gas treating apparatus according to the present invention, the exhaust gas circulates and the granular material having the adsorption capacity or resolution of the exhaust gas flows, and a plurality of the present invention provided above the moving bed. And a powdery or granular material supply device.

Here, it is preferable to use a carbonaceous adsorbent such as activated carbon, a catalyst or the like as the powder or granular material. In the exhaust gas treatment apparatus configured in this way, the powder or granular material is supplied to the moving bed from the powder or granular material supply device of the present invention, and the exhaust gas is circulated through the moving bed to be adsorbed by the adsorbing ability of the powder or granular material, Alternatively, it is decomposed by the resolution of the granular material. As described above, wear of the chute of the powder or granular material supply device is sufficiently suppressed when the powder or granular material is supplied, so that the life of the device is extended by reducing the frequency of exchanging the chute, and by extension the maintainability of the device. And the economical efficiency can be improved.

Further, the powder or granules may be distributed widely within the particle size of, for example, about 1 to 9 mm, originally or with the operation of the exhaust gas treating apparatus. When the powder or granular material having such a particle size distribution is circulated and used in the exhaust gas treatment device, if the powder or granular material supply device of the present invention having a plurality of the chutes of the present invention is used, the drift of the exhaust gas in the moving bed is suppressed. It becomes possible.

Preferably, the moving layer is composed of a plurality of regions partitioned by partition walls extending in a substantially vertical direction, and the chute of the powdery- or granular-material feeder has the following formula (3): 0.2≤La / Lb≤ 0.5 (3), it is useful if provided so as to satisfy the relationship represented by. Here, in the formula, La represents the width of the shoot, and Lb
Indicates the width in the direction orthogonal to the direction in which the exhaust gas flows in the horizontal cross section of the region.

In this case, the granular material supplied downward from the chute of the granular material supplying device flows into a plurality of regions of the moving bed and moves (flows down) in each of these regions. That is, the granular material divides each region in the moving bed. At this time, if the chute satisfies the relationship of the above formula (3), the powder and granules are likely to be uniformly distributed to each region, and the particle size distribution of the powder and granules flowing in each region is easily achieved. Therefore, it is possible to sufficiently suppress the uneven flow of the exhaust gas such that the exhaust gas flows through the specific region.

In the present invention, the term "powder granules" refers to a plurality of powdery or granular solid particles (for example, carbonaceous adsorbent particles such as activated carbon, catalyst particles, etc.). The aggregate or the aggregate may be used, and the geometrical or three-dimensional shape is not particularly limited, and examples thereof include those having a spherical shape, a cylindrical shape, a cylindrical shape, and the like.

[0021]

BEST MODE FOR CARRYING OUT THE INVENTION Embodiments of the present invention will be described in detail below. The same elements will be denoted by the same reference symbols, without redundant description. Further, the positional relationship such as up, down, left and right is based on the positional relationship shown in the drawings unless otherwise specified.

FIG. 1 is a schematic diagram showing an exhaust gas treating apparatus according to the present invention. The exhaust gas processing device 100 includes an adsorption reaction tower 110 and a desorption regeneration tower 120, and transfer devices 131, 13 such as conveyors are provided between them.
2 are installed. The transfer devices 131 and 132 are arranged so that one end of each of them is located below and above the adsorption reaction tower 110, and that the other end of each of them is located above and below the desorption regeneration tower 120, respectively. It is arranged. These transfer machines 131 and 132 are for transferring a carbonaceous adsorbent described later between the adsorption reaction tower 110 and the desorption regeneration tower 120. The carbonaceous adsorbent is supplied to the adsorption reaction tower 110 and the desorption regeneration tower 120 from the upper end portion, flows down through the inside of each, and is discharged from the lower end portion to the outside.

Further, the adsorption reaction tower 110 has an exhaust gas supply section 18 and a treated gas discharge section 20 on its side wall. Exhaust gas W is introduced into the exhaust gas supply unit 18. The exhaust gas W undergoes desulfurization (adsorption of SOx components) by a carbonaceous adsorbent, dust removal, and the like while flowing so as to traverse the inside of the adsorption reaction tower 110, and the treated gas is discharged as the treated gas Ws. Stack from part 20 (chimney) 140
Sent to. It is also possible to denitrate the exhaust gas W (decompose NOx components) by supplying reduced nitrogen N such as ammonia together with the exhaust gas W to the adsorption reaction column 110.

SOx in the exhaust gas W in the desorption regeneration tower 120
The carbonaceous adsorbent having adsorbed the components is sent to the desorption regeneration tower 120 by the transfer device 131, and the SOx component is desorbed by heating in the desorption regeneration tower 120. The desorbed, so to speak, concentrated SOx gas is recovered as a by-product (sulfuric acid or the like) in the recovery unit 150. The sieving machine 16 is provided between the lower end of the desorption / regeneration tower 120 and the other end of the transfer device 132.
0 is set. The carbonaceous adsorbent regenerated in the desorption / regeneration tower 120 is sorted according to particle size by the sieving machine 160, and the carbonaceous adsorbent having a particle diameter of a predetermined size or more is transferred by the transfer machine 132 to the adsorption reaction tower 110. Will be returned to.

FIG. 2 shows an exhaust gas treating apparatus 100 shown in FIG.
FIG. 3 is a perspective view (partially cutaway view) schematically showing the structure of the main part (adsorption reaction tower) of FIG. In the adsorption reaction tower 110, a body 13 having a rectangular cross section is connected below an upper hopper 12 having a conical shape,
A lower hopper 14 having an inverted cone shape (funnel shape) is connected below the body portion 13. Further, inside the body portion 13, a pair of moving layers 1 facing each other and arranged in parallel with each other.
0 and 10 are formed.

Further, at the upper end of the upper hopper 12, there is provided a supply port 15 into which a carbonaceous adsorbent 17 (powder particles) such as granular activated carbon is introduced. On the other hand, a discharge port 16 for the carbonaceous adsorbent 17 is provided at the lower end of the lower hopper 14. The carbonaceous adsorbent 17 supplied to the upper hopper 12 through the supply port 15 is used for each moving bed 10 and the lower hopper 1.
4, and is discharged to the outside of the adsorption reaction tower 110 through the discharge port 16. The transfer devices 131 and 132 (see FIG. 1) described above are provided below the discharge port 16 and the supply port 15, respectively.
Is located above.

Furthermore, the exhaust gas supply unit 18 and the treated gas discharge unit 20 are arranged on one side and the other side wall of the body 13, respectively. From the exhaust gas supply section 18 to the body section 13
The exhaust gas W introduced into the inside is divided into right and left in the supply direction, flows through each moving layer 10, becomes the treated gas Ws, joins in the treated gas discharge part 20, and is discharged from there. It

The moving layer 10 is a space defined by an inlet louver 10a and an outlet louver 10b therebetween. The inlet louver 10a has an opening structure so that the flowing-down carbonaceous adsorbent 17 does not pass through and flow out to the outside, while the outlet louver 10b is a porous plate. The diameter of each hole of the outlet louver 10b is also set so that the carbonaceous adsorbent 17 flowing down does not pass through and flow out. With such a structure, the carbonaceous adsorbent 17 surely flows down in the moving bed 10, and the exhaust gas W and the treated gas Ws can pass through each moving bed 10. Further, a plurality of partition walls 9 (compartment walls) are installed between the inlet louver 10a and the outlet louver 10b so as to be substantially orthogonal to them and at predetermined intervals. By these, the moving layer 10 is divided into a plurality of regions.

A plurality of cutting devices 22 such as a roll feeder rotated by a drive system (not shown) are arranged at the lower end of each moving layer 10. These cutting device 2
No. 2 is such that the filling level of the carbonaceous adsorbent 17 in the moving bed 10 is adjusted to be constant while the carbonaceous adsorbent 17 is discharged from the discharge port 16.
Is for discharging a fixed amount at a time. With such a configuration, the carbonaceous adsorbent 17 in each moving bed 10 can be flowed down at a desired constant speed.

FIG. 3 is a sectional view (partially omitted) taken along line III-III in FIG. 2, mainly showing the internal structure of the upper hopper 12 which constitutes the adsorption reaction tower 110. 4 is a sectional view taken along the line IV-IV in FIG. Note that the drawing of the upper hopper 12 is omitted in FIG. Further, FIG. 5 is a sectional view taken along line VV in FIG.

As shown, inside the upper hopper 12,
A segregation prevention device 1 (powder and grain supply device) including an internal hopper 2 (hopper portion) and a plurality of (four in the present embodiment) chutes 3 is provided. The internal hopper 2 has an inverted cone shape (funnel shape), and a discharge portion 2b having a substantially cylindrical shape is provided in communication with a lower portion of a supply portion 2a to which the carbonaceous adsorbent 17 is supplied. . Further, the inner hopper 2 has an adjustment margin C in the horizontal direction, is appropriately positioned within the range of the adjustment margin C, and is fixed at a predetermined position. The value of the adjustment margin C is not particularly limited, but, for example, considering the installation accuracy of the members, it is preferable that the center of the cross section of the internal hopper 2 can be adjusted by ± 50 mm in the north, south, east, and west directions.

The chute 3 is formed by connecting side plates 43 to both edges of a main plate 41 (main plate part) on which a plurality of plate-shaped sub plates 42 (sub plate parts) are provided in a protruding manner. These chutes 3 are connected at their upper ends via a stage 5 and extend radially. In FIG. 4, two of the four chutes 3 are arranged such that the lower ends thereof are located above the moving layers 10. It is preferable that two or more chutes 3 are installed for one moving layer 10.

In addition, the inlet louver 10a and the outlet louver 10
As described above, each moving layer 10 formed between the moving layer 10 and b is partitioned along the flow direction of the exhaust gas W by the perforated plates 10c and 10d, and the moving layers 10 are formed by the plurality of partition walls 9 described above. It is further divided in the longitudinal direction. Further, the moving layers 10 and 10 are connected to each other at the upper end of the inlet louver 10a via the tower top and the convex member 12a having the inclined surface.

The operation of the segregation prevention system 1 in the exhaust gas treatment system 100 thus constructed will be described below. The carbonaceous adsorbent 17 transferred by the transfer device 132 shown in FIG. 1 or the carbonaceous adsorbent 17 newly added to the exhaust gas treatment device falls from the supply port 15 of the upper hopper 12 into the upper hopper 12. Are introduced continuously by. The carbonaceous adsorbent 17 is supplied from the supply unit 2a to the internal hopper 2 and passes through the inside thereof to fall from the discharge unit 2b to the central portion on the stage 5. The carbonaceous adsorbent 17 forms a free surface having an angle of repose mainly determined by its particle size distribution on the stage 5 and accumulates in a mountain shape (aggregates 17a (powder particles) shown in FIGS. 3 and 5). reference).

The carbonaceous adsorbent 17 further supplied onto the stage 5 overflows from the surface of the aggregate 17a and is supplied to the upper end of the chute 3, and the main plate 4 is inclined by the inclination of the chute 3.
Run down along 1. Here, FIG. 6 is a cross-sectional view (partially omitted) schematically showing a main part of the chute 3 and a state in which the carbonaceous adsorbent 17 is flowing down the chute 3.
A part of the carbonaceous adsorbent 17 that flows down is prevented from flowing by the sub-plate 42 located at the top, and is deposited on the upstream side in the vicinity of the joint (entanglement) between the main plate 41 and each sub-plate 42.

At this time, the surface of the accumulated body 17c (powder particles) of the deposited carbonaceous adsorbent 17 forms a free surface having the angle of repose θa determined by the particle size distribution described above. Carbonaceous adsorbent 1 that cannot be stopped by the uppermost sub-plate 42
7 flows down so as to slide down on the stack 17c, is blocked by the sub-plates 42 located further downstream, and is sequentially deposited on the upstream side of each sub-plate 42. Eventually, the carbonaceous adsorbent 17 is blocked by all the sub-plates 42, and the upper surfaces of the main plate 41 and the sub-plates 42 are entirely covered with the carbonaceous adsorbent 17. Further, the supplied carbonaceous adsorbent 17 slides (slides) downward on the aggregate 17c along the chute 3.

As a result, the carbonaceous adsorbent 17 drops downward from the chute 3 and is supplied onto the predetermined area of each moving layer 10. In a normal steady operation state, the carbonaceous adsorbent 17 thus supplied is continuously and quantitatively discharged from the moving bed 10 at a downflow speed corresponding to each region while being filled in the entire moving bed 10. It Therefore, the carbonaceous adsorbent 1 is provided in the space just above the moving bed 10 inside the upper hopper 12.
The state in which 7 is filled in a predetermined amount is maintained. The level of the carbonaceous adsorbent 17 overflowing from the chute 3 differs depending on the filling level, and the carbonaceous adsorbent 17 is piled up in a mountain shape having a free surface determined by the angle of repose even above the moving bed 10 (Fig. 3 and the aggregate 17b (powder / granular body) shown in FIG. 5), and then flows into the moving bed 10.

Here, the main plate 41 constituting the chute 3
Is preferably the following formula (1); θa ≦ θs ≦ θa + 30 ° (1), more preferably the following formula (4); θa ≦ θs ≦ θa + 20 ° (4), particularly preferably the following formula (5) ); Θa ≦ θs ≦ θa + 10 ° (5), so as to satisfy the relationship represented by Here, in the formula, θa represents the angle of repose (°) formed by the carbonaceous adsorbent 17, and θs represents a predetermined angle (°) formed by the main plate 41 with respect to the horizontal direction. As a specific example of the angle of repose θa, in the case of a granular activated carbon having a cylindrical shape as the carbonaceous adsorbent 17 having a particle size distribution of about 1 to 9 mm,
It becomes about 32 °. However, the numerical value is not limited to this.

If this θs is less than θa, the carbonaceous adsorbent 17 is only deposited on the chute 3 and is difficult to flow down on the chute 3. On the other hand, when θs exceeds θa + 30 °, the flow rate of the carbonaceous adsorbent 17 becomes excessive (unnecessarily).
The carbonaceous adsorbent 17 that is increased and discharged downward from the lower end of the chute 3 may be biased toward the side wall of the body 13.

The sub plate 42 protruding from the main plate 41 is
Preferably, the following formula (2); Lp ≦ H × 4 (2), more preferably the following formula (6); H ≦ Lp ≦ H × 2 (6), is provided so as to satisfy the relationship. . Here, in the formula, Lp represents the interval (arrangement interval) between the sub plates 42, and H represents the height H of the sub plate 42 from the surface of the main plate 41. Specifically, when the columnar granular activated carbon having a particle size distribution with a particle size of about 1 to 9 mm flows down as the carbonaceous adsorbent 17, for example, H is set to about 50 mm and Lp is 185 mm.
It can be a degree. However, the numerical values are not limited to these.

When this Lp exceeds H × 4, the main plate 41
It becomes difficult for the entire upper surface of the main plate 41 to be covered with the carbonaceous adsorbent 17, and thus a part of the main plate 41 may be exposed. When this happens, dynamic contact between the flowing carbonaceous adsorbent 17 and the main plate 41 tends to occur. Further, when Lp is less than H, the number of sub-plates 42 increases, which is disadvantageous in cost, and the flow resistance of the carbonaceous adsorbent 17 due to the sub-plates 42 may undesirably increase.

Further, returning to FIG. 4, the shoot 3 is preferably the following formula (3); 0.2 ≦ La / Lb ≦ 0.5 (3), more preferably the following formula (7); 0.25 ≦ La / Lb ≦ 0.4 (7), It is preferable that it is provided so as to satisfy the relationship represented by. Here, in the formula, La represents the width of the shoot 3, and L
b is the longitudinal width of the region partitioned in the moving layer 10, that is, the exhaust gas W in the horizontal cross section of the region.
Indicates the width in the direction orthogonal to the circulation direction of. Specifically, for example, the entire width in the longitudinal direction of the moving layer 10 is 6 to 10 m.
When Lb is about 1 m, La is 20 to
It can be about 50 cm. However, the numerical values are not limited to these.

If La / Lb is less than 0.2, the falling range of the carbonaceous adsorbent 17 supplied downward from the chute 3 is significantly narrowed, and the carbonaceous adsorbent is provided in a specific region of the moving bed 10. 17 may be unevenly distributed. On the other hand, when La / Lb exceeds 0.5, the particle size distribution of the carbonaceous adsorbent 17 tends to be different in each region.
Further, when the condition of the expression (3) is satisfied, there is an advantage that it is easy to prevent the flow velocity of the carbonaceous adsorbent 17 on the chute 3 from being excessively small or excessively large.

According to the segregation prevention apparatus 1 and the exhaust gas treatment apparatus 100 using the segregation prevention apparatus 1 configured as described above, one of the carbonaceous adsorbents 17 supplied from the stage 5 and flowing down the chute 3 is used as described above. The parts are blocked by the sub plate 42, and the upper surfaces of the main plate 41 and the sub plate 42 are entirely covered with the carbonaceous adsorbent 17. Therefore, the deposited carbonaceous adsorbent 17
Serves as a liner (a so-called “self-liner”) that covers the upper surface of the chute 3, and direct and dynamic contact between the carbonaceous adsorbent 17 flowing down along the chute 3 and the main plate 41 and the sub-plate 42 is prevented. . Therefore, wear of the chute 3 due to contact between the flowing carbonaceous adsorbent 17 and the main plate 41 and the sub-plate 42 can be sufficiently prevented. As a result, the frequency of exchanging the chute 3 can be reduced, and the maintainability and economy of the exhaust gas treatment device 100 can be improved.

Further, since the chute 3 is opened above the main plate 41, it is more difficult to close the chute 3 than the one using the conventional pipe type chute. Further, since the segregation prevention device 1 is covered with the upper hopper 12, the carbonaceous adsorbent 17 and the exhaust gas W are discharged to the outside of the adsorption reaction tower 110 even if the chute 3 is broken or broken. Dissipation forks never spread. From these things, the exhaust gas treatment device 1
The reliability of 00 can be improved. Furthermore, since the carbonaceous adsorbent 17 and the exhaust gas W do not dissipate or diffuse to the outside, even if such an abnormality should occur, it is easier to recover as compared with the conventional case using the pipe chute. Is.

Further, when the number of the shoots 3 is one, as described above, the carbonaceous adsorbent 17 having a particle size distribution is used.
When the particles are dropped and deposited, those having a larger particle size tend to accumulate in the peripheral portion and those having a smaller particle size tend to accumulate in the central portion. In this case, a large amount of particles having a large particle size are supplied to the region of the moving layer 10 formed at a position far from the chute 3. In this case, inconvenience such as uneven flow of the exhaust gas W may occur.

On the other hand, since the exhaust gas treating apparatus 100 is provided with a plurality of each chute 3 for one moving bed 10, the carbonaceous adsorbent 17 supplied to each region of the moving bed 10 is provided.
The particle size distribution of can be sufficiently homogenized. That is, segregation of the carbonaceous adsorbent 17 having a particle size distribution can be sufficiently prevented. Therefore, it is possible to suppress the occurrence of a short path of the exhaust gas W flowing through the moving layer 10 and the increase in pressure loss. As a result, it is possible to reliably prevent a reduction in the processing efficiency such as the desulfurization rate and the denitration rate of the exhaust gas W.

Furthermore, when the main plate 41 is provided so as to satisfy the relationship represented by the formula (1), the deterioration of the fluidity of the carbonaceous adsorbent 17 can be sufficiently suppressed, and the carbonaceous adsorbent can be sufficiently suppressed. It is possible to sufficiently prevent the flow velocity of 17 from excessively increasing. Therefore, it is possible to reliably supply the carbonaceous adsorbent 17 downward and to prevent the carbonaceous adsorbent 17 from being biasedly supplied to a specific portion of the moving layer 10.
As a result, the particle size distribution of the carbonaceous adsorbent 17 flowing down in each region of the moving bed 10 can be further homogenized, the short path of the exhaust gas W flowing through the moving bed 10 is generated, and the pressure loss is reduced. Further increase can be prevented. Therefore, it is possible to further prevent a reduction in the processing efficiency such as the desulfurization rate and the denitration rate from the exhaust gas W.

In addition, when the sub-plate 42 is provided so as to satisfy the relationship expressed by the equation (2), it becomes easy to cover the entire upper surface of the main plate 41 with the carbonaceous adsorbent 17. Therefore, the main plate 4
It is possible to prevent a part of 1 from being exposed. Thereby, the dynamic contact between the carbonaceous adsorbent 17 and the main plate 41 is reliably prevented, and the wear of the chute 3 can be further suppressed. Therefore, the frequency of exchanging the chute 3 can be further reduced, and the maintainability and economy of the exhaust gas treatment device 100 can be further improved.

Further, since the internal hopper 2 has the adjustment margin C capable of adjusting the installation position along the horizontal direction, the position where the carbonaceous adsorbent 17 is dropped from the internal hopper 2 can be easily matched with the center of the stage 5. be able to. Thereby, the carbonaceous adsorbent 17 can be evenly supplied to each chute 3. Therefore, the amount and the particle size of the carbonaceous adsorbent 17 supplied downward from each chute 3 can be further homogenized. Further, since the internal hopper 2 is positioned by the adjustment margin C and the internal hopper 2 is fixed at that position, the internal hopper 2 is moved during the operation of the exhaust gas treatment device 100 (during supply of the carbonaceous adsorbent 17). Positional deviation can be reliably prevented.

Further, when the chute 3 is provided so as to satisfy the relationship expressed by the equation (3), the falling range of the carbonaceous adsorbent 17 supplied downward from the chute 3 becomes remarkably narrow. Can be suppressed. Further, in this case, there is also an advantage that it is easy to prevent the flow rate of the carbonaceous adsorbent 17 on the chute 3 from becoming too small or too large. As a result, the carbonaceous adsorbent 17 is provided in a specific region of the moving bed 10.
The uneven flow of the exhaust gas W due to the uneven distribution of can be suppressed. Further, when the condition of Expression (3) is satisfied, it is possible to further prevent a difference in particle size distribution of the carbonaceous adsorbent 17 from occurring in each region.

In the above-described embodiment, the number of members of the chute 3 and the stage 5 of the segregation prevention device 1 and their connecting structure are not limited to those shown in the drawings. As another configuration, for example, the segregation prevention device 7 configured as shown in FIG. 7 can be exemplified. FIG. 7: is a top view which shows typically the structure of other embodiment which concerns on the granular material supply apparatus by this invention. The segregation prevention device 7 is formed by connecting the lower end of each chute 3 of the segregation prevention device 1 shown in FIG. In the case shown in the figure, the carbonaceous adsorbent 17 is supplied to one moving bed 10 from six locations above the moving bed 10 to further prevent segregation.

Further, the segregation prevention devices 1 and 7 may be used for supplying the powdery particles other than the carbonaceous adsorbent 17. Examples of other powder and granules include powdery or granular catalysts, carbon particles, various granules,
Examples include various crushed bodies, beans, dried fruits, and grains obtained by crushing them, milling, and the like. The segregation prevention device of the present invention is extremely effective as a device for supplying powdery or granular material to a transfer device for powdery or granular materials, or a column tank such as a storage tank, a storage tank, a silo, or a reaction tower such as a blast furnace. It is something.

[0054]

As described above, according to the powdery- or granular-material feeding device of the present invention, since the chute having the main plate portion on which the sub-plate portion is provided is provided, the upper surface of the chute is entirely powdery or granular. The dynamic contact between the chute and the chute, which is covered with and flows (flows down), is effectively prevented. As a result, it is possible to reliably prevent the chute from being worn. Further, since the exhaust gas treatment device of the present invention has the plurality of powdery or granular material supply devices of the present invention, the uneven flow of the exhaust gas can be prevented and the reduction of the exhaust gas treatment efficiency can be sufficiently prevented. Moreover, since the wear of the chutes is suppressed, the frequency of exchanging the chutes, which are the constituent members, can be reduced, that is, the life of the device can be extended. As a result, the maintainability and economy of the exhaust gas treatment device can be improved.

[Brief description of drawings]

FIG. 1 is a configuration diagram schematically showing an exhaust gas treatment apparatus according to the present invention.

FIG. 2 is a perspective view schematically showing a structure of a main part (adsorption reaction tower) of the exhaust gas treating apparatus shown in FIG.

3 is a sectional view (partially omitted) taken along the line III-III in FIG.

4 is a sectional view taken along line IV-IV in FIG.

5 is a cross-sectional view taken along line VV in FIG.

FIG. 6 is a cross-sectional view showing a main part of the chute and a state in which a carbonaceous adsorbent is flowing down the chute.

FIG. 7 is a plan view schematically showing the configuration of another embodiment of the powdery or granular material feeder according to the present invention.

[Explanation of symbols]

1, 7 ... Segregation prevention device (powder / granule supply device), 2 ... Internal hopper (hopper part), 3 ... Chute, 5 ... Stage, 9 ...
Partition wall (partition wall), 10 ... Moving layer, 17a, 17b, 17
c ... Aggregate (powder / granule), 17 ... Carbonaceous adsorbent (powder / granulate), 41 ... Main plate (main plate part), 42 ... Sub plate (sub plate part),
100 ... Exhaust gas treatment device, 110 ... Adsorption reaction tower, 120
… Desorption regeneration tower, C… adjust, W… exhaust gas, Ws… treated gas, θa… repose angle.

─────────────────────────────────────────────────── ─── Continuation of front page (51) Int.Cl. ⁷ Identification code FI B01D 53/81 ZAB B01D 53/34 123B 53/94 129B B01J 4/00 105 53/36 101A 8/12 331 B65G 11/16 ( 56) References JP-A-59-26804 (JP, A) JP-A-8-332347 (JP, A) Actually opened 54-93981 (JP, U) Actually opened 55-101697 (JP, U) (58) ) Fields surveyed (Int.Cl. ⁷ , DB name) B65G 65/32 B01D 53/34 ZAB B01D 53/81 ZAB B01J 4/00 105 B01J 8/12 331 B65G 11/16

Claims (3)

(57) [Claims] 1. A powdery- or granular-material supplying device for supplying powdery or granular materials downward, wherein a main plate portion extending at a predetermined angle with respect to the horizontal, and projectingly provided on the main plate portion. A plurality of sub-plate portions arranged at a predetermined interval along the extending direction of the main plate portion, and a plurality of chutes to which the powder and granules are supplied, and the plurality of chutes. At the upper end of each chute,
The stage to be bonded and the stage above which the powder and granules are introduced.
And a hopper part that is provided with the stage , and the stage includes a surface of the accumulated aggregate of the particles.
Overflow from above to direct the granules to the multiple chutes.
And a plurality of chutes are coated on the periphery of the chutes . 2. The hopper unit is installed in a horizontal position.
Has an adjustable margin for adjusting the position, The powdery or granular material supply device according to claim 1, wherein 3. Exhaust gas is circulated, and the adsorption capacity of the exhaust gas or
A moving bed in which a granular material having a resolution flows The method according to claim 1 or 2, which is provided above the moving layer.
And a granular material supply device, wherein the moving layer is in a substantially vertical direction.
Consisting of multiple areas partitioned by partition walls extending to The chute of the powdery- or granular-material feeder has the following formula (3); 0.2 ≦ La / Lb ≦ 0.5 (3), La: width of the shoot, Lb: The exhaust gas flows in the horizontal cross section of the region
Satisfy the relation expressed by the width in the direction orthogonal to the
Was set up, An exhaust gas treatment device characterized by the above.